DE112019006931T5 - Crack sensor system - Google Patents

Abstract

The present invention comprises: crack detection wiring (80) having a plurality of main element lines (A, B, C) each of which has one end formed as a terminal (a, b, c) and the other ends are connected to each other, and an auxiliary element line (D) having an adjacent element line section (D1) which is provided in correspondence with at least one main element line B out of the plurality of main element lines (A, B, C) and which lies along the one main element line (B), and a remote element line section (D2) which is connected to the adjacent element line section (D1) and which is farther away from the one main element line (B) than the adjacent element line section (D1); and a calculating device (90) which performs a logical calculation on the basis of the line state between a pair of terminals of the plurality of main element lines (A, B, C) and the line state of the auxiliary element line (D), whereby the location of a break in the main element lines (A, B, C) is specified.

Description

Technical area

The present invention relates to a crack sensor system.

This present application claims priority based on the Japanese Patent Application No. 2019-034786 , which was filed in Japan on February 27, 2019, the contents of which are incorporated herein by reference.

State of the art

Metal or concrete elements and devices are known to crack (brittle) due to aging, wear and tear, and unexpected heat or force. In a case where such cracks grow, there is a risk that the element will break. Therefore, various techniques have been proposed which can instantly detect occurrence of such cracks.

For example, the crack sensor and crack monitoring device described in PTL 1 below include a common line and a plurality of test lead wires extending to both sides in a direction intersecting the common line. The common line and test lead wires are attached to the surface of the element to be monitored. If a crack occurs in the element in an area through which a test lead wire passes, the one test lead wire is broken. By detecting this interruption, it is possible to recognize that a crack has occurred in the element at least in the area through which the one measuring lead wire runs.

Further, the crack sensor described in PTL 2 below is configured to detect a growth direction and a growth rate of the crack by tracing the order of the test lead wires in which the disconnection occurs when the crack grows over the plurality of test lead wires (branch lines) described above.

List of quotes

Patent literature

• [PTL 1] Japanese Patent No. 6189344
• [PTL 2] Japanese Patent No. 5971797 Summary of the invention

Technical problem

However, although the crack sensors described in PTL 1 and PTL 2 can detect that a crack has occurred on the broken test lead wire, it is difficult to specify the exact position of the crack on the test lead wire. It is possible to increase the number of test lead wires, but it is not practical because the increase causes complicated wiring. For this reason, there is an increasing demand for a technique capable of specifying a location of occurrence of cracks with higher accuracy without unduly increasing the number of wirings.

The present invention has been made to solve the above problems, and its object is to provide a crack sensor system capable of specifying a location of occurrence of cracks with higher accuracy and evaluating the degree of crack expansion.

Solution to the problem

A crack sensor system according to an aspect of the present invention includes: crack detection wiring that has a plurality of main element lines each of which is provided to extend along a wall surface and each of which has one ends formed as terminals and the other ends connected to each other , and an auxiliary element line having an adjacent element line portion which is provided in correspondence with at least one main element line among the plurality of main element lines and which lies along the one main element line, and a distant element line portion which is connected to the adjacent element line portion and which is further away from the one main element line than the adjacent element line portion; and a computing device that performs logical computation based on conduction states between terminal pairs of the plurality of main element lines and a conduction state of the auxiliary element line to specify a location of a break in the main element lines.

According to the above configuration, it is possible to specify which main element line is broken by performing a logical calculation through the calculating device based on the combination of the conduction states between the pair of terminals on the plurality of main element lines. That is, by specifying the main element broken line, the location where the crack occurs on the wall surface can be specified.

Further, in the above configuration, there is provided an auxiliary element line that corresponds to a main element line. The auxiliary element line has an adjacent element line section, which lies along the one main element line, and one distant element line section which is farther away from the one main element line than the one adjacent element line section. The calculation device performs a logical calculation in consideration of the conduction state of the auxiliary element lines in addition to the plurality of main element lines. For example, in a case where a crack occurs in a part of the wall surface through which the adjacent element line section passes, the adjacent element line section and the part lying along the adjacent element line section at a main element line are interrupted at the same time. Therefore, in a case where a break occurs in the adjacent element line portion, it can be determined that a crack has occurred in the part of the main element line lying along the adjacent element line portion.

On the other hand, in a case where no break has occurred in the adjacent element line portion, it can be determined that a crack has occurred in a part of the main element line different from the part lying along the adjacent element line portion.

As described above, according to the above configuration, an auxiliary element line is provided in addition to the main element line, and a part of the auxiliary element line is provided along the main element line. Therefore, it is possible to easily specify a break position on the main element line, that is, a place where the crack occurs on the wall surface.

A crack sensor system according to an aspect of the present invention includes: crack detection wiring that has a plurality of main element lines each of which is provided to extend along a wall surface and each of which has one ends formed as terminals and the other ends connected to each other and an auxiliary element line provided in correspondence with at least one main element line among the plurality of main element lines, extending along the one main element line, and having a breaking strength different from a breaking strength of the one main element line; and a computing device that performs logical computation based on conduction states between terminal pairs of the plurality of main element lines and a conduction state of the auxiliary element line to specify a location of a break in the main element lines.

According to the above configuration, the breaking strength of the auxiliary element line and the breaking strength of the main element line are different. Therefore, in a case where a crack occurs in the part through which the main element line and the auxiliary element line pass, either the main element line or the auxiliary element line is broken first.

For example, in a case where the breaking strength of the auxiliary element line is higher than the breaking strength of the main element line, the main element line is broken before the auxiliary element line. By detecting this, the occurrence of cracks can be recognized at an early stage in which the extent thereof is small immediately after the occurrence.

In the crack sensor system, the main element line can have a breaking strength to such an extent that the main element line is broken at the same time when a crack occurs on the wall surface, and the auxiliary element line can have a higher breaking strength than the one main element line.

According to the above configuration, the main element line has a breaking strength to such an extent that the main element line is simultaneously broken when the crack occurs. Therefore, in a case where a crack occurs in the part through which the main element line and the auxiliary element line pass, only the main element line is broken immediately at the same time as the occurrence.

In this way, by detecting a state in which only the main element line is broken and the auxiliary element line is not broken, cracks can be detected immediately at the same time as they occur.

Further, by detecting that the auxiliary element line is broken after the main element line is broken, it is possible to detect that the crack that has already occurred continues to expand.

In the crack sensor system, the main element line can have a breaking strength to such an extent that the main element line is broken at the same time when a crack occurs on the wall surface, and the auxiliary element line can have a breaking strength lower than the main element line and also have a breaking strength to such an extent that that in a case where a shear force is generated on the wall surface, the auxiliary element line is broken by the shear force before the crack occurs.

According to the above configuration, the auxiliary element line has a breaking strength to such an extent that the auxiliary element line is broken before the occurrence of the crack. In one Therefore, in the case where a crack occurs in the part where the main element line and the auxiliary element line run, only the auxiliary element line is first broken due to the shear force before the occurrence thereof.

In this way, by detecting a state in which only the auxiliary element line is broken and the main element line is not broken, an indication of crack can be recognized before the occurrence.

Further, by detecting that the main element line is broken after the auxiliary element line is broken, it is possible to detect that a crack actually occurs in the part where the sign thereof is present.

In the crack sensor system, the auxiliary element line may include the adjacent element line portion that is located along at least one main element line among the plurality of main element lines, and the distal element line portion that is connected to the adjacent element line portion and that is farther from the one main element line than the adjacent element line portion.

According to the above configuration, in a case where a crack occurs in a part of the wall surface through which the adjacent element line portion passes, the adjacent element line portion and the part lying along the adjacent element line portion at a main element line are interrupted at the same time.

Therefore, in a case where a break occurs in the adjacent element line portion, it can be determined that a crack has occurred in the part of the main element line lying along the adjacent element line portion or that there is an indication of occurrence thereof.

On the other hand, in a case where no break has occurred in the adjacent element line portion, it can be determined that a crack has occurred in a part of the main element line different from the part lying along the adjacent element line portion, or that an indication of Occurrence of which is present.

As described above, according to the above configuration, an auxiliary element line is provided in addition to the main element line, and a part of the auxiliary element line is provided along the main element line. Therefore, it is possible to easily specify a break position on the main element line, that is, a place where the crack occurs on the wall surface.

Advantageous Effects of the Invention

According to the present invention, it is possible to provide a crack sensor system capable of specifying a location of occurrence of cracks with higher accuracy.

Figure list

• 1 Fig. 13 is a circuit diagram showing a configuration of a crack sensor system according to a first embodiment of the present invention.
• 2 Fig. 13 is a table showing an example of conduction states between terminals in the crack sensor system according to the first embodiment of the present invention.
• 3 FIG. 13 is an explanatory diagram showing a state of a wall surface corresponding to the table of FIG 2 is equivalent to.
• 4th Fig. 13 is a table showing another example of the conduction states between terminals in the crack sensor system according to the first embodiment of the present invention.
• 5 FIG. 13 is an explanatory diagram showing a state of a wall surface corresponding to the table of FIG 4th is equivalent to.
• 6th Fig. 13 is a circuit diagram showing a first modification example of the crack sensor system according to the first embodiment of the present invention.
• 7th Fig. 13 is a circuit diagram showing a second modification example of the crack sensor system according to the first embodiment of the present invention.
• 8th Fig. 13 is a circuit diagram showing a third modification example of the crack sensor system according to the first embodiment of the present invention.
• 9 Fig. 13 is a circuit diagram showing a configuration of a crack sensor system according to a second embodiment of the present invention.
• 10 Fig. 13 is a circuit diagram showing a configuration of a crack sensor system according to a third embodiment of the present invention.
• 11 Fig. 13 is a circuit diagram showing another modification example of the crack sensor system according to the first embodiment of the present invention.
• 12th Fig. 13 is an example of a table showing time changes in the conduction states between terminals in the crack sensor system according to the first embodiment of the present invention.
• 13th Fig. 13 is another example of a table showing time changes in conduction states between terminals in the crack sensor system according to the first embodiment of the present invention.

Description of embodiments

[First embodiment]

The first embodiment of the present invention will be described with reference to FIG 1 until 5 described. The crack sensor system according to the present embodiment is a device for detecting occurrence of cracks (crevices) in a target member made of, for example, metal or concrete.

As in 1 shown includes the crack sensor system 100 a crack detection wiring 80 and a computing device 90 . The crack detection wiring 80 is arranged on a wall surface W of the target element. The computing device 90 is electrical with the crack detection wiring 80 and specifies presence or absence of cracks and their positions based on a conduction state of the crack detection wiring 80 .

The crack detection wiring 80 has several (three) main element lines A. , B. and C. and an auxiliary element line D. The main element lines A. , B. and C. are laid along the wall surface W at intervals from one another.

The main element lines A. , B. and C. are formed from an electrically conductive metal material including, for example, copper and aluminum. Regardless of whether the wall surface W is a flat surface or a curved surface, the main element lines become A. , B. and C. laid so that they follow the shape of the wall surface W.

Further, in a case where a crack occurs on the wall surface W, a break occurs immediately on a part of the main element lines A. , B. and C. that cuts the crack. In other words, the main element lines point A. , B. and C. each has a tensile strength (breaking strength) to such an extent that the line is immediately broken in a case where a crack occurs.

Clamps a , b and c are at one end of the main element lines A. , B. respectively. C. intended. Connecting lines 91 differing from the calculating device described later 90 extend are with the clamps a , b and c tied together. The other ends of the main element lines A. , B. and C. are linked together to form a knot P. to form the clamps a , b , c and the knot P. are also arranged on the wall surface W.

The clamps a , b , c and the knot P. are arranged on the wall surface W at a distance from each other. Here it is desirable that the clamps a , b and c are arranged in an area on the wall surface W where cracks are unlikely to occur and the knot P. is provided in an area on the wall surface W where cracks are particularly likely to occur. It is also desirable that the clamps a , b and c are spaced from each other.

The auxiliary element line D. extends along the main element line B. under the above three main element lines A. , B. and C. One end of the auxiliary element line D. is a clamp d and the other end is with the knot mentioned above P. tied together.

The auxiliary element line D. extends from the knot P. and has an adjacent element line section D1 that is relatively close to the main element line B. and a removed element line portion D2 , the one with the adjacent element line segment D1 is connected and is arranged so that it is relatively further from the main element line B. than the neighboring element line segment D1 away is on.

The neighboring element line segment D1 extends in the same direction as the main element line B. The element line segment removed D2 is with one end side of the adjacent element line portion D1 connected and extending in the same direction as the adjacent element line segment D1 at a position that is from the main element line B. away. The part of the main element line B. along the adjacent element line segment D1 is as a first part B1 shown and the part without the first part B1 (i.e. the part that corresponds to the removed element line segment D2 corresponds to) is as a second part B2 shown. In a case where in the first part B1 a crack occurs, the adjacent element line portion become D1 and the first part B1 interrupted at the same time due to the crack.

In other words, the adjacent element line segment is located D1 to such an extent close to the first part B1 (Main element line B. ) that the same crack causes an interruption at the same time. The removed element line segment D2 and the main element line B. are sufficiently spaced apart to such an extent that a single crack covering the removed element line section D2 and the principal element line portion B. overstretched, does not occur.

Like the main element lines A. , B. and C. is also the auxiliary element line D. formed from an electrically conductive metal material including copper and aluminum. Regardless of whether the wall surface W is a flat surface or a curved surface, the auxiliary element line is D. laid so as to follow the shape of the wall surface W. Further, in a case where a crack occurs on the wall surface W, a break occurs immediately on a part of the auxiliary element line D. that cuts the crack. In other words, the auxiliary element line points D. like the main element lines A. , B. and C. exhibits a tensile strength (breaking strength) to such an extent that the line is immediately broken in a case where a crack occurs.

In a case of laying the main element lines A. , B. and C. and the auxiliary element line D. on the wall surface W, for example, a method of performing thermal spraying on a metal material on the wall surface W can be used. Alternatively, a method of obtaining a desired wiring pattern by partially removing the metal film previously applied to the wall surface W by laser irradiation can be used. It is also possible to use these main element lines A. , B. and C. and the auxiliary element line D. than to form a physical wiring by using a very thin wire.

In addition, it is also possible to use a method using a 3D printer such as additive manufacturing technology and AM technology.

The computing device 90 is through the connecting lines 91 electrically with the terminals described above a , b , c and d tied together. The computing device 90 performs a logical calculation based on the state of the current passing through the crack detection wiring 80 flows (line status).

For example, in the in 2 shown state line between the terminal c and the clamp a and between the clamp d and the clamp a available. That is, between the main element line A. and the main element line C. and between the main element line A. and the auxiliary element line D. line is available.

The other hand is between the clamp a and the clamp b and between the clamp b and the clamp c no line available. That is, between the main element line A. and the main element line B. and between the main element line B. and the main element line C. there is no line.

In the above state, the computing device performs 90 based on the input that “the terminal a and the clamp c direct the clamp a and the clamp b not conduct and the clamp b and the clamp c do not pass ”, performs a logical calculation and determines that“ a break on the main element line B. occured".

Since "the clamp d and the clamp a conduct ”, it is further determined that“ no break on the auxiliary element line D. is available". As a result, the computing device determines 90 that the location where the break occurs is “a position that is on the main element line B. and no break in the auxiliary element line D. caused ". That is, as in 3 shown, the part at which the interruption occurs is referred to as "the second part B2 at the main element line B “specified.

Furthermore, in the in 4th shown state line between the terminal c and the clamp a available. That is, the main element line A. and the main element line C. conduct. The other hand is between the clamp a and the clamp b , between the clamp b and the clamp c and between the clamp d and the clamp a no line available.

That is, there is no line between the main element line A. and the main element line B. , between the main element line B. and the main element line C. and between the auxiliary element line D. and the main element line A. is available.

In this state, the computing device performs 90 based on the input that “the terminal a and the clamp c direct the clamp a and the clamp b not conduct and the clamp b and the clamp c do not pass ”, performs a logical calculation and determines that“ a break on the main element line B. occured". Since "the clamp d and the clamp a do not direct ”, it is further determined that“ the auxiliary element line D. and the main element line B. are interrupted at the same time ".

As a result, the computing device determines 90 that the location where the break occurs is “a position that is on the main element line B. and a break also at the auxiliary element line D. caused ". As described above, there is the adjacent element line portion D1 at the auxiliary element line D. near the first part B1 at the main element line B. Therefore, as in 5 shown the place where the Interruption occurs as "the first part B1 at the main element line B “specified.

According to the above configuration, the computing device performs 90 a logical calculation based on the combination of the line conditions between the pair of terminals in the several (three) main element lines A. , B. and C. It is therefore possible to specify which of the main element lines A. , B. and C. is interrupted.

That is, by specifying the main element broken line, the location where the crack occurs on the wall surface W can be specified. Further, in the above configuration, is the auxiliary element line D. provided, the one main element line B. is equivalent to.

The auxiliary element line D. indicates the adjacent element line segment D1 along the main element line B. and the removed element line segment D2 that is from the main element line B. farther away than the neighboring element line segment D1 is on.

The computing device 90 performs a logical calculation taking into account the line condition of the auxiliary element line D. in addition to the main element lines A. , B. and C. For example, in a case where a crack occurs in a part of the wall surface W, the adjacent element line portion D1 runs, the adjacent element line segment D1 and the part (first part B1 ), which extends along the adjacent element line section D1 at the main element line B. is located, interrupted at the same time. Therefore, in a case where there is a break in the adjacent element line portion D1 is present, it can be determined that the crack is in the first part B1 at the main element line B. occurs.

On the other hand, if in the adjacent element line section D1 there is no break, it can be determined that a crack in one part (second part B2 ) has occurred which differs from the part which extends along the adjacent element line section D1 at the main element line B. is located, differs.

As described above, according to the above configuration, is the auxiliary element line D. in addition to the main element lines A. , B. and C. and is part of the auxiliary element line D. provided along a main element line. Therefore, it is possible to easily specify a break position on the main element line, that is, a location where the crack occurs on the wall surface W, with high accuracy.

The first embodiment of the present invention has been described above. It should be noted that the above configuration can be changed and modified into various forms without departing from the scope of the present invention. For example, in the first embodiment, an example has been described in which the adjacent element line portion is located D1 at the auxiliary element line D. from the knot P. extends.

The mode of the auxiliary element line D. however, is not limited to the above and the in 6th The configuration shown (first modification example) can be used. In the example of the drawing is an adjacent element line segment D1a an auxiliary element line There at an intermediate position from the node P. to the clamp d intended. A pair of removed element line segments D2a is with both ends of the adjacent element line section D1a tied together. With such a configuration, it is possible to locate the break point on the main element line B. to be specified in the same way as described above.

Further, as another example (second modification example), one as shown in FIG 7th configuration shown can be used.

In the example of the drawing there are clamps d1 and d2 at both ends of an auxiliary element line section Db intended. The auxiliary element line Db extends in a U-shape from the clamp d1 to the clamp d2 between the main element line B. and the main element line A. .

At the auxiliary element line Db becomes the part near the main element line B. as an adjacent element line segment D1b designated. Also are the clamp d1 and the clamp d2 each with the above-mentioned calculating device 90 tied together. With such a configuration, it is possible to locate the break point on the main element line B. to be specified in the same way as described above.

As a still further example (third modification example), the 8th configuration shown can be used.

In the example of the drawing there are clamps d1 and d2 at both ends of an auxiliary element line section Dc provided as in the second modification example. The auxiliary element line Dc extends annularly from the clamp d1 to the clamp d2 between the main element line B. and the main element line A. At the auxiliary element line Dc becomes the part near the main element line B. referred to as an adjacent element line section Die.

Specifically, in this modification example, is the position of the adjacent element line section D1c in the direction of the side of the knot compared to the second modification example P. aligned. One end of the adjacent element line segment D1c is directly with the clamp d1 tied together. Also are the clamp d1 and the clamp d2 each with the above-mentioned calculating device 90 tied together. With such a configuration, it is possible to locate the break point on the main element line B. to be specified in the same way as described above.

Further, as a change common to the first embodiment, the first modification example, the second modification example, and the third modification example, the auxiliary element line D. also in accordance with the main element line A. or C. instead of the main element line B. It is also possible to use several of the crack detection wirings described above 80 to combine. As a result, crack detection can be realized in a larger area.

[Second embodiment]

The second embodiment of the present invention will now be described with reference to FIG 9 described. The same components as those in the first embodiment are represented by the same reference numerals, and detailed descriptions thereof are not repeated.

In the present embodiment, crack detection has wiring 280 the main element lines mentioned above A. , B. and C. and the auxiliary element line E. on.

The auxiliary element line E. extends along the main element line B. under the main element lines A. , B. and C. In particular, the auxiliary element line extends E. at a position near the main element line B. in the same direction. In other words, the auxiliary element line E. at the position near the main element line B. provided to such an extent that tensile stress is applied thereto due to occurrence of a crack in a case where a single crack occurs in the area of the wall surface W through which the main element line B. runs.

One end of the auxiliary line E. is a clamp e and the other end is with the knot mentioned above P. The auxiliary element line E. is formed from a material having a breaking strength different from that of the material from which the main element lines are made A. , B. and C. are formed.

In particular is the auxiliary element line E. formed from a metal material having a higher tensile strength than that of the material from which the main element lines A. , B. and C. On the other hand, the main element lines A. , B. and C. each have a tensile strength (breaking strength) to such an extent that in a case where a crack occurs on the wall surface W, an interruption occurs at the same time as the crack occurs.

According to the above configuration, the breaking strength is the auxiliary element line E. and the breaking strength of the main element lines A. , B. and C. different. In a case where a crack occurs in the part through which the main element line B. and the auxiliary element line E. therefore either the main element line will run first B. or the auxiliary element line E. interrupted.

For example, in a case where the breaking strength of the auxiliary element line E. higher than the breaking strength of the main element line B. is, the main element line B. before the auxiliary element line E. By detecting this, the occurrence of cracks can be recognized at an early stage in which the extent thereof is small immediately after the occurrence.

According to the above configuration, the main element line further has a breaking strength to such an extent that the main element line B. is interrupted at the same time when the crack occurs. In a case where a crack occurs in the part through which the main element line B. and the auxiliary element line E. therefore only the main element line will run B. interrupted immediately at the same time as the occurrence.

In this way, by detecting a state in which only the main element line B. is broken and the auxiliary element line E. is not interrupted, cracks are detected immediately at the same time as they occur. Further, it is by detecting that the auxiliary element line E. is broken after the main element line B. interrupted, it is possible to detect that the crack that has already occurred is expanding further.

The second embodiment of the present invention has been described above. It should be noted that the above configuration can be changed and modified into various forms without departing from the scope of the present invention. For example, in the above-described second embodiment, a configuration for ensuring a difference in breaking strength by using different materials for the main element lines was made A. , B. and C. and the auxiliary element line E. described.

However, in order to make the breaking strength different, it is also possible to use a configuration in which the diameter of the auxiliary element line E. is set to be larger than the diameter of the major element lines A. , B. and C. is while the main element lines A. , B. and C. and the auxiliary element line E. are formed from the same material.

It is also possible to use the auxiliary element line E. to be arranged so that they line up with the main element line A. or C. instead of the main element line B. It is also possible to use several of the crack detection wirings described above 280 to combine. As a result, crack detection can be realized in a larger area.

Further, it is also possible to use a configuration in which the auxiliary element line E. has an adjacent element line portion and a distant element line portion described in the first embodiment above.

[Third embodiment]

Next, the third embodiment of the present invention will be described with reference to FIG 10 described. The same components as those in the above embodiments are represented by the same reference numerals, and detailed description thereof is not repeated.

As shown in the drawing, in the present embodiment, crack detection has wiring 380 the main element lines mentioned above A. , B. and C. and auxiliary element line F. The auxiliary element line F. extends along the main element line B. under the main element lines A. , B. and C. .

In particular, the auxiliary element line extends F. at a position near the main element line B. in the same direction. In other words, in a case where a single crack occurs in the area of the wall surface W through which the main element line B. runs, the auxiliary element line F. at a position near the main element line B. provided to such an extent that the auxiliary element line F. receives a shear force (tensile stress) before the crack occurs.

One end of the auxiliary line F. is a clamp f and the other end is with the knot mentioned above P. The auxiliary element line F. is formed from a material with a breaking strength different from that of the material from which the main element lines are made A. , B. and C. In particular, the auxiliary element line is F. formed from a metal material having a lower tensile strength (breaking strength) than that of the material from which the main element lines A. , B. and C. are formed.

In particular, the auxiliary element line F. has a breaking strength to such an extent that, in a case where a shear force causing a crack is generated on the wall surface W, there is an interruption by the shear force before the crack occurs. On the other hand, the main element lines A. , B. and C. has a breaking strength to such an extent that in a case where a crack occurs on the wall surface W, an interruption is simultaneously present when the crack occurs.

According to the above configuration, the auxiliary element line has F. a breaking strength to such an extent that the auxiliary element line F. interrupted before the crack occurs. In a case where a crack occurs in the part where the main element line B. and the auxiliary element line F. therefore, only the auxiliary element line will run before the occurrence thereof F. interrupted first. In this way, by detecting a state in which only the auxiliary element line F. is broken and the main element line B. is not interrupted, a sign of crack can be detected before it occurs.

Further, it is by detecting that the main element line B. is interrupted after the auxiliary element line F. has been interrupted, it is possible to detect that a crack actually occurs in the part where the sign of it is present.

The third embodiment of the present invention has been described above.

It should be noted that the above configuration can be changed and modified into various forms without departing from the scope of the present invention. For example, in the third embodiment, the configuration for securing the difference in breaking strength was made by using different materials for the main element lines A. , B. and C. and the auxiliary element line F. described.

However, in order to make the breaking strength different, it is also possible to use a configuration in which the diameter of the auxiliary element line F. is set to be smaller than the diameter of the major element lines A. , B. and C. is while the main element lines A. , B. and C. and the auxiliary element line F. are formed from the same material.

It is also possible to use the auxiliary element line F. to be arranged so that they line up with the main element line A. or C. instead of the main element line B. furthermore it is also possible to use several of the crack detection wirings described above 380 to combine. As a result, crack detection can be realized in a larger area.

Further, it is also possible to use a configuration in which the auxiliary element line F. the adjacent element line segment D1 and the removed element line segment D2 which are described above in the first embodiment.

Further, in the first embodiment described above, it is also possible to use a configuration in which another element line portion is removed D3 along the removed element line segment D2 is provided (see 11 ). In this case, based on the fact that the element line sections removed D2 and D3 are not interrupted, be determined that the first part B1 of the main element line segment B. is interrupted.

That is, according to this configuration, the break position is on the main element line portion B. can be specified more precisely.

In addition, it is also possible to use a configuration in which a time change for the determination of the line states of 2 and 4th described in the first embodiment is added.

For example, as in 12th is shown in a case where there is a time lag between the break times of the main element line B. and the auxiliary element line D. is present, be determined that the second part B2 the main element line B. is interrupted at a time t3 and the auxiliary element line D. is interrupted at a time tx.

In the case of 12th it is difficult to specify which of the adjacent element line section D1 and the removed element line segment D2 is interrupted. However, in a case where the conduction state as shown in FIG 13th shown, the interruption times for the main element line are shown B. and the auxiliary element line D. same. Therefore, it can be determined that the interruption is in the first part B1 the main element line B. and in the adjacent element line section D1 occurred at time t3.

Although the preferred embodiments of the present invention have been described in detail above, the present invention is not limited to such specific embodiments and can be modified and changed into various forms within the scope of the present invention described in the claims.

Industrial applicability

The present invention is applicable to crack sensor systems.

List of reference symbols

100

Crack sensor system

80, 280, 380

Crack detection wiring

90

Computing device

91

Connecting line

A, B, C

Main element line

B1

first part

B2

second part

D, Da, Db, Dc, E, F

Auxiliary element line

D1, D1a, D1b, D1c

adjacent element line segment

D2, D2a, D2b, D2c, D3

removed element line segment

P.

node

a, b, c, d, e, f, d1, d2, d3

Clamp

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• JP 2019034786 [0002]
• JP 6189344 [0005]
• JP 5971797 [0005]

Claims (5)

Crack sensor system, comprising: a crack detection wiring comprising a plurality of main element lines each of which is provided to extend along a wall surface and each having one ends formed as terminals and the other ends connected to each other, and an auxiliary element line with an adjacent element line portion that is provided in correspondence with at least one main element line among the plurality of main element lines and which lies along the one main element line and has a distal element line portion which is connected to the adjacent element line portion and which is farther from the one main element line than the adjacent element line portion; and a computing device that performs logical computation based on conduction states between terminal pairs of the plurality of main element lines and a conduction state of the auxiliary element line to specify a location of a break in the main element lines. Crack sensor system, comprising: a crack detection wiring, the plural main element lines, each of which is provided to extend along a wall surface, and each having one ends formed as terminals and the other ends connected to each other, and an auxiliary element line, which in correspondence with at least a main element line is provided among the plurality of main element lines, extends along the one main element line and has a breaking strength different from a breaking strength of the one main element line; and a computing device that performs logical computation based on conduction states between terminal pairs of the plurality of main element lines and a conduction state of the auxiliary element line to specify a location of a break in the main element lines. Crack sensor system Claim 2 wherein the main element line has a breaking strength to such an extent that the main element line is simultaneously broken when a crack occurs on the wall surface, and the auxiliary element line has a higher breaking strength than the one main element line. Crack sensor system Claim 2 , wherein the main element line has a breaking strength to such an extent that the main element line is interrupted at the same time when a crack occurs on the wall surface, and the auxiliary element line has a breaking strength lower than the main element line and also has a breaking strength to such an extent that Case where a shear force is generated on the wall surface, the auxiliary element line is broken by the shear force before the crack occurs. Crack sensor system according to one of the Claims 2 until 4th wherein the auxiliary element line comprises the adjacent element line portion that lies along at least one main element line below the plurality of main element lines, and the removed element line portion that is connected to the adjacent element line portion and that is farther from the one main element line than the adjacent element line portion.

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